KR101787311B1 - Pulse change display system using pulse analysis application - Google Patents

Abstract

By detecting the pulse of yourself and others and using the pulse analysis application of the smartphone to calculate and synchronize the synchronization between the pulse of one's own person and the pulse of another person, the climax of mutual pulse change can be confirmed A plurality of bio-signal detectors for acquiring bio-signals, wirelessly transmitting the bio-signals obtained, and a display device for displaying bio-signals transmitted from the plurality of bio-signal detectors. And a biometric information confirmation terminal for calculating a synchro rate of a change of a plurality of bio-signals using a pulse analysis application and displaying an operation result as an event, thereby implementing a pulse change display system using a pulse analysis application.

Description

[0001] Pulse change display system using pulse analysis [0002]

[0001] The present invention relates to a pulse change display system using a pulse analysis application, and more particularly, to a pulse change display system using a pulse analysis application that detects a pulse of itself and others and uses the pulse analysis application of a smart phone to synchronize the pulse change of one's own pulse And displaying the pulse-change-related information to calculate a climax of the mutual pulse change.

It is widely known that pulse detection is performed according to various functions of the smartphone, or pulse waves are analyzed using a pulse analysis application, and the results of the analysis are displayed.

In particular, in the case of Xiaomi band, it can be detected by a smartphone while wearing it simply on the wrist.

In addition, a conventional technique for detecting biometric information using an information device such as a smart phone and displaying the biometric information for managing health or expressing a state of excited state is disclosed in Patent Documents 1 to 3 Lt; / RTI >

In the prior art disclosed in Patent Document 1, a bio-signal measured by a portable health meter is continuously stored in a smart phone received by a local communication network or the like, so that a one-time bio-signal measured by a portable health meter is collected, And to compare the bio-signals measured in the past with the bio-signals measured in the past and to suggest the behavior direction such as the amount of alcohol according to the health state of each individual and the type of alcohol to be consumed I can do it.

The conventional art disclosed in Patent Document 2 is a method of processing contents based on a bio-signal, which includes acquiring a bio-signal of a user and changing the type or characteristic of the content to be output based on the bio- And processes or replaces the content based on the determined parameter, and outputs the processed or replaced content.

In the prior art disclosed in Patent Document 3, a volumetric pulse wave is measured at a position of a different body by using a smart device and a wearable device, and a blood flow velocity index and a blood pressure index are calculated Cardiovascular assessment system and a cardiovascular assessment program that can provide indicators as indicators of cardiovascular assessment.

Korean Registered Patent No. 10-1249274 (Registered on March 23, 2013) (Self-diagnostic system for bio-signal using smart phone) Korean Patent Laid-Open Publication No. 10-2015-0039113 (published on April 28, 2014) (a method of processing contents based on bio-signals, and a device therefor) Korean Patent Laid-Open No. 10-2016-0150347 (published on December 30, 2016) (smart device and wearable device interaction-based cardiovascular evaluation system and cardiovascular evaluation program)

However, the pulse detection and analysis method and the conventional techniques using the general smartphone as described above can detect and analyze the own pulse or one person's biological signal (in particular, pulse) and display the result. However, It is impossible to display and analyze the pulse rate and display the pulse rate of the other person or the pulse rate of the pulse rate change of the other person.

In other words, in a certain state (especially in an excited state), the pulse state of the other party is checked in real time by using an information device such as a smart phone, or the pulse of the other party and the change of the own pulse are calculated, There are disadvantages that are impossible.

Accordingly, the present invention has been proposed in order to solve the above-mentioned general pulse sensing and pulse analysis methods and the related art problems, and it is an object of the present invention to provide a pulse analysis method and a pulse analysis method, The present invention has an object to provide a pulse change display system using a pulse analysis application which can confirm a climax of mutual pulse change by calculating a synchronization of a pulse and a pulse change of another person and expressing the synchronization thereof .

In order to achieve the above object, a preferred embodiment of the pulse change display system using the pulse analysis application according to the present invention comprises a plurality of bio-signal detectors for acquiring bio-signals and wirelessly transmitting the bio-signals acquired; And a biometric information confirmation terminal for displaying the biometric signal transmitted from the plurality of biometric signal sensors, calculating a synchronization rate of change of a plurality of biometric signals using a pulse analysis application, and displaying the result of the calculation as an event .

Each of the bio-signal detectors of the plurality of bio-signal detectors is worn on the wrist in the form of a band to sense the pulse as a bio-signal, and converts the detected bio-signal into a near-field wireless signal and transmits it.

Wherein the biometric information confirmation terminal comprises: a bio-signal receiver for receiving bio-signals transmitted from the plurality of bio-signal detectors; And a display unit for visually displaying the received biometric signal.

The biometric information confirmation terminal may include a controller for controlling the analysis of the plurality of received biometric information and controlling the generation of an event according to the analysis result; And an application execution unit for executing a pulse analysis application in cooperation with the control unit.

The biometric information verification terminal may further include a bio-signal analyzing unit for analyzing the bio-signal using a pulse analysis application executed by the application executing unit to calculate a synch rate of change of the first and second pulse signals .

The biometric information verification terminal may further include an event generation unit for generating an event corresponding to a synchronization rate of a pulse change analyzed by the bio-signal analysis unit under the control of the control unit.

The event generating unit may change the sound effect based on the result of the sync rate calculation of the pulse change or automatically select and output the corresponding music.

According to the present invention, the pulse of the self and another person is detected, and the pulse rate of the own pulse is compared with the pulse rate of the other person's pulse using the pulse analysis application of the smartphone, There is an advantage that the climax of the mutual pulse change can be confirmed.

1 is a block diagram of a first embodiment of a pulse change display system using a pulse analysis application according to the present invention;
FIG. 2 is a block diagram of a second embodiment of a pulse change display system using a pulse analysis application according to the present invention;
FIG. 3A and FIG. 3B are views showing an example in which the synchronization rate of the pulse change of the self and the other person is displayed in the present invention. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a pulse change display system using a pulse analysis application according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

≪ Example 1 >

1 is a block diagram of a pulse change display system using a pulse analysis application according to a first preferred embodiment of the present invention.

The pulse change display system using the pulse analysis application according to the present invention includes first and second bio-signal sensors 110 and 120 for acquiring bio-signals and wirelessly transmitting the bio-signals obtained, A bio-signal detector 110 (120) for displaying a bio-signal, computing a synchronization of a change of a plurality of bio-signals using a pulse analysis application, and displaying biometric information And a confirmation terminal 200.

Here, the first living body signal sensor 110 is a living body signal sensor for sensing its own living body signal, and the second living body signal sensor 120 is a living body signal sensor for detecting a living body living body signal. In the present invention, a pulse signal is described as an example. The present invention is not limited to this, and it is possible to express a change by applying various bio-signals in the same way.

Since the configuration and operation of the first and second bio-signal detectors 110 and 120 are the same, only one bio-signal detector (for example, the first bio-signal detector) will be described below for convenience of explanation .

The first bio-signal detector 110 includes a bio-signal acquisition unit 101 for acquiring a pulse of a measurement subject as a bio-signal, a bio-signal acquisition unit 102 for converting the bio- And a power supply unit 103 for supplying a driving power source. Herein, the short range wireless signal may use various known short range wireless signals, but the present invention uses Bluetooth (4.0).

The first and second bio-signal detectors 110 and 120 are implemented in the form of bands. The first and second bio-signal detectors 110 and 120 detect a pulse as a bio-signal in a state of being worn on the wrist of a measurement subject and convert the detected bio- .

Here, the bio-signal obtained by the first bio-signal sensor 110 is referred to as a "first pulse signal", and the bio-signal acquired by the second bio-signal sensor 120 is referred to as a "second pulse signal".

In addition, although the biometric information confirmation terminal 200 can be implemented by various information devices, the present invention will be described as an embodiment implemented by a smart phone. The bio-information confirmation terminal 200 includes a bio-signal receiver 201 for receiving bio-signals transmitted from the first and second bio-signal detectors 110 and 120, a display unit for visually displaying the received bio- A control unit 203 for controlling the analysis of a plurality of received biometric information and controlling the generation of an event according to the analysis result, and an application executing unit 204 for executing a pulse analysis application in cooperation with the control unit 203 .

Here, the pulse analysis application expresses two pulse signals as the number of lamps, calculates the synch rate of the pulse change, calculates the result, expresses the two pulse signals as the color concentration, and calculates the sync rate of the pulse change Means software that produces results.

In addition, the biometric information confirmation terminal 200 calculates a synchronization rate of change of the first and second pulse signals using the pulse analysis application executed by the application execution unit 204, The analyzer 205 may further include an event generator 206 for generating an event corresponding to a synchronization rate of a pulse change analyzed by the bio-signal analyzer 205 under the control of the controller 203 .

Here, it is preferable that the event generating unit 206 changes the sound effect based on the result of the sync rate calculation of the pulse change or automatically selects and outputs the corresponding music.

The operation of the pulse change display system using the pulse analysis application according to the first preferred embodiment of the present invention will now be described in detail.

First, the first and second bio-signal detectors 110 and 120, which acquire a pulse signal of a measurement subject as a bio-signal, are worn on the wrists of a person who wants to check the synchronization rate with himself / herself. Synchronous rate confirmation here refers to identifying a pulse change in a particular state (e.g., an excited state).

The bio-signal acquisition unit 101 of the first bio-signal sensor 110 acquires the pulse of the measurement subject as a bio-signal using a pulse sensor (for example, PR320) already known for pulse measurement. The pulse signal thus obtained is converted into a local wireless signal (Bluetooth signal) through the bio-signal transmitter 102, and is wirelessly transmitted in a Bluetooth manner.

In addition, the second living body signal detector 120 operates in the same manner as the first living body signal detector 110, detects a pulse signal as a living body signal, and wirelessly transmits the living body signal in a Bluetooth manner.

The pulse signals obtained from the self and the other person are received through the bio-signal receiving unit 201 of the biometric information confirmation terminal 200, which is a smartphone. At this time, the biometric information confirmation terminal 200 assumes that the pulse analysis application has been executed through the application execution unit 204. [ The bio-signal receiving unit 201 preferably acquires a bio-signal using a Bluetooth communication system. Here, since the Bluetooth system communicates with each other through a procedure called pairing, the biometric information confirmation terminal 200 first receives the biometric signal through pairing with one biometric signal sensor, then disconnects the connection, It is preferable to pair with a signal detector to receive a living body signal. That is, all the pulse signals generated from the two bio-signal detectors are received through the alternate operation.

The display unit 202 of the biometric information confirmation terminal 200 displays the biometric information received by the biometric signal receiver 201 on the screen. This allows the verifier to identify his / her pulse changes and other person's pulse changes in a specific state (e.g., an excited state) using his or her smartphone.

When the bio-signal is received, the control unit 203 controls the bio-signal analysis unit 205 to control the synchronization rate of the pulse change of the self and the other person.

In response to this control, the bio-signal analyzer 205 calculates the synchronization of the changes of the first and second pulse signals using the pulse analysis program included in the pulse analysis application.

Here, the pulse-rate synchro rate calculation converts the first and second pulse signals into a specific bar graph, and superimposes each converted bar graph to calculate a pulse-change synchro rate in a specific state. In converting a pulse signal into a bar graph, a bar graph table may be prepared corresponding to a pulse level, and when the pulse level is detected, the bar graph table may be searched to extract a corresponding bar graph.

The method of superimposing two bar graphs according to two pulse signals is as follows. As shown in FIG. 3A, the bar graph of the first pulse signal is located at the upper portion, the bar graph of the second pulse signal is located at the lower portion, The result of the calculation is that two bar graphs change according to the degree of change.

As another method, the pulse-rate synchro rate calculation converts the first and second pulse signals into a specific color concentration, and superimposes the concentrations of the respective converted colors to calculate a pulse-change synchronization rate in a specific state. In converting the pulse signal into the color density, a color concentration table may be provided corresponding to the pulse level, and when the pulse level is sensed, the concentration table of the color may be searched to extract the concentration of the corresponding color.

The method of superimposing the two color density data according to the two pulse signals is a method of superposing the density data of the color of the first pulse signal and the density data of the color of the second pulse signal as shown in Fig. Can be used. As another method, it is also possible to use a method of separately converting each pulse signal into color density data, and separately displaying them.

The operation result of the pulse rate change rate calculated by the bar graph or the color concentration is displayed on the screen through the display unit 202 so that the user can change his / her pulse change state, pulse change state of the other party, So that the pulse rate change rate of the pulse can be confirmed.

Likewise, the other person can confirm the sync rate of the pulse change of himself / herself in the same manner as described above.

The result of the pulse-rate synchronization rate calculation derived from the bio-signal analyzer 205 is transmitted to the event generator 206. The event generator 206 generates an event corresponding to the transmitted pulse- .

Here, events may occur in various ways, but it is preferable to use functions basically provided in a general smart phone.

For example, it is possible to vary the sound effect (sound pitch) or automatically select and output corresponding music based on the calculation result of the pulse rate change synchronization rate. The user can adjust the sound level and music selection according to the pulse rate change sync rate in advance.

≪ Example 2 >

Meanwhile, in the first embodiment, the smartphone itself generates an event related to the calculation result of the pulse-rate synchronization rate in the smartphone, and it is also possible to extend the same to generate additional events using another event generating device .

2, the second embodiment of the pulse change display system using the pulse analysis application according to the present invention is a system for acquiring a living body signal and for generating a first and a second living body signal The first and second bio-signal detectors 110 and 120 may be configured to detect the bio-signals transmitted from the bio-signal detectors 110 and 120. The bio-signals transmitted from the first and second bio- A biometric information confirmation terminal 200 for displaying an operation result as an event and transmitting the event as a short distance wireless signal, an event processing unit 200 for processing the event signal transmitted from the biometric information confirmation terminal 200, And an event handler 300 for generating an event.

Here, the first and second bio-signal detectors 110 and 120 operate in the same manner as the first and second bio-signal detectors 110 and 120 of FIG.

The biometric information verification terminal 200 further includes an event information transmission unit 207 for transmitting only the event information in the form of a short distance wireless signal to the configuration of the biometric information verification terminal of FIG.

The event processor 300 includes an event information receiving unit 301 for receiving event information using a short-range wireless communication signal, a synchronous rate control unit 302 for synchronizing a pulse rate of a pulse change according to event information received by the event information receiving unit 301 And an event processing unit 302 for expressing the event.

The event processing unit 302 may display an event by combining the sync rate of the pulse change with the number of the lamps, express the sync rate of the pulse change by the color density change, or emit a smell corresponding to the sync rate of the pulse change, .

The operation of the pulse change display system using the pulse analysis application according to the second preferred embodiment of the present invention will now be described in detail.

First, the first and second bio-signal detectors 110 and 120, which acquire a pulse signal of a measurement subject as a bio-signal, are worn on the wrists of a person who wants to check the synchronization rate with himself / herself. Synchronous rate confirmation here refers to identifying a pulse change in a particular state (e.g., an excited state).

The bio-signal acquisition unit 101 of the first bio-signal sensor 110 acquires the pulse of the measurement subject as a bio-signal using a pulse sensor (for example, PR320) already known for pulse measurement. The pulse signal thus obtained is converted into a local wireless signal (Bluetooth signal) through the bio-signal transmitter 102, and is wirelessly transmitted in a Bluetooth manner.

In addition, the second living body signal detector 120 operates in the same manner as the first living body signal detector 110, detects a pulse signal as a living body signal, and wirelessly transmits the living body signal in a Bluetooth manner.

The pulse signals obtained from the self and the other person are received through the bio-signal receiving unit 201 of the biometric information confirmation terminal 200, which is a smartphone. At this time, the biometric information confirmation terminal 200 assumes that the pulse analysis application has been executed through the application execution unit 204. [ The bio-signal receiving unit 201 preferably acquires a bio-signal using a Bluetooth communication system. In this case, since the Bluetooth system communicates with each other through a procedure called pairing, the biometric information confirmation terminal 200 first receives the biometric signal through pairing with one biometric signal sensor, then disconnects the connection, It is preferable to pair with a signal detector to receive a living body signal. That is, all the pulse signals generated from the two bio-signal detectors are received through the alternate operation.

The display unit 202 of the biometric information confirmation terminal 200 displays the biometric information received by the biometric signal receiver 201 on the screen. This allows the verifier to identify his / her pulse changes and other person's pulse changes in a specific state (e.g., an excited state) using his or her smartphone.

When the bio-signal is received, the control unit 203 controls the bio-signal analysis unit 205 to control the synchronization rate of the pulse change of the self and the other person.

In response to this control, the bio-signal analyzer 205 calculates the synchronization of the changes of the first and second pulse signals using the pulse analysis program included in the pulse analysis application.

Here, the pulse-rate synchro rate calculation converts the first and second pulse signals into a specific bar graph, and superimposes each converted bar graph to calculate a pulse-change synchro rate in a specific state. In converting a pulse signal into a bar graph, a bar graph table may be prepared corresponding to a pulse level, and when the pulse level is detected, the bar graph table may be searched to extract a corresponding bar graph.

The method of superimposing two bar graphs according to two pulse signals is as follows. As shown in FIG. 3A, the bar graph of the first pulse signal is located at the upper portion, the bar graph of the second pulse signal is located at the lower portion, The result of the calculation is that two bar graphs change according to the degree of change.

As another method, the pulse-rate synchro rate calculation converts the first and second pulse signals into a specific color concentration, and superimposes the concentrations of the respective converted colors to calculate a pulse-change synchronization rate in a specific state. In converting the pulse signal into the color density, a color concentration table may be provided corresponding to the pulse level, and when the pulse level is sensed, the concentration table of the color may be searched to extract the concentration of the corresponding color.

The method of superimposing the two color density data according to the two pulse signals is a method of superposing the density data of the color of the first pulse signal and the density data of the color of the second pulse signal as shown in Fig. Can be used. As another method, it is also possible to use a method of separately converting each pulse signal into color density data, and separately displaying them.

The operation result of the pulse rate change rate calculated by the bar graph or the color concentration is displayed on the screen through the display unit 202 so that the user can change his / her pulse change state, pulse change state of the other party, So that the pulse rate change rate of the pulse can be confirmed.

Likewise, the other person can confirm the sync rate of the pulse change of himself / herself in the same manner as described above.

The result of the pulse-rate synchronization rate calculation derived from the bio-signal analyzer 205 is transmitted to the event generator 206. The event generator 206 generates an event corresponding to the transmitted pulse- .

Here, events may occur in various ways, but it is preferable to use functions basically provided in a general smart phone.

For example, it is possible to vary the sound effect (sound pitch) or automatically select and output corresponding music based on the calculation result of the pulse rate change synchronization rate. The user can adjust the sound level and music selection according to the pulse rate change sync rate in advance.

Also, the event information transmission unit 207 converts the pulse-rate synchronization rate calculation result obtained by the bio-signal analysis unit 205 into a short distance wireless signal and transmits it to the event processor 300.

The event processor 300 receives the calculation result of pulse rate change synchronization rate through the event information receiver 301 as event information and the event processor 302 calculates the pulse rate change rate based on the calculation result of the pulse rate change synchronization rate And emits a fragrance to process an event according to the calculation result of the pulse change synchronous rate.

In addition, the event processing unit 302 can process the event in the form of a bar graph in the same manner as the biometric information confirmation terminal 200, using the result of the pulse rate change synchronization rate calculation. It is also possible to display the operation result.

As described above, according to the present invention, it is also possible to display the pulse change state of the user and the pulse change state of the other person in a specific state through the smartphone pulse application, calculate the pulse change synchronous rate of the self and the other person, It is possible to make them mutually confirmed through visual, auditory, and olfactory changes according to the change of the eyes.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It is obvious to those who have.

The present invention is applied to a technique of superimposing a pulse signal of a person and a person, and calculating a pulse rate change rate and displaying it.

110, 120: first and second bio-signal detectors
101: biological signal acquisition unit
102: biometric signal transmission unit
103:
200: Biometric information identification terminal
201; The bio-
202:
203:
204: Application execution unit
205: biological signal analysis unit
206: Event generator
207: Event information transmission unit
300: Event Handler
301: Event information receiving unit
302: Event processor

Claims (11)

A system for expressing a pulse-rate synchro rate using a pulse analysis application of a smartphone,
A plurality of biological signal detectors for acquiring biological signals and wirelessly transmitting the acquired biological signals; And
And a biometric information identification terminal for displaying the biometric signal transmitted from the plurality of biometric signal detectors, calculating a synchronous rate of a plurality of biometric signal changes using a pulse analysis application, and displaying an operation result as an event,
Wherein the biometric information verification terminal comprises: a control unit for controlling analysis of a plurality of received biometric information and controlling an occurrence of an event according to an analysis result; an application execution unit for executing a pulse analysis application in cooperation with the control unit; And a bio-signal analyzing unit for analyzing a bio-signal by a method of calculating a synch rate of change of the first and second pulse signals using the executed pulse analysis application,
The bio-signal analyzing unit converts the first and second pulse signals into a specific bar graph using the pulse analysis program included in the pulse analysis application, superimposes the converted bar graphs, And the pulse rate is calculated to analyze the living body signal.
The bio-signal analyzer according to claim 1, wherein the plurality of bio-signal detectors are worn on a wrist of a subject to be measured in the form of a band to detect a pulse as a bio-signal, and convert the detected bio-signal into a near- Pulse change display system using application.
The biometric information identification terminal according to claim 1, wherein the biometric information identification terminal is implemented as a smart phone,
Wherein the biometric information confirmation terminal includes a display unit for visually displaying the received biometric signal.
The bio-information analysis terminal of claim 1, further comprising an event generation unit for generating an event corresponding to a synchronization rate of a pulse change analyzed by the bio-signal analysis unit under the control of the control unit. Pulse change display system used.
The biometric information verification terminal of claim 4, wherein the biometric information identification terminal displays the result of analyzing the biometric information by the calculation of the pulse rate change synchronization rate,
Wherein the event generating unit automatically varies the sound effect or automatically selects the corresponding music based on the result of the synchro rate calculation of the pulse change, and outputs the selected music.
The biometric information identification terminal of claim 1, wherein the biometric information identification terminal expresses an event by combining the sync rate of the pulse change with the number of the lamps, or expresses the sync rate of the pulse change by the color concentration change. Change display system.
It is a system that calculates pulse rate change rate using the pulse analysis application of smartphone and displays the result.
A plurality of biological signal detectors for acquiring biological signals and wirelessly transmitting the acquired biological signals;
Displays bio-signals transmitted from the plurality of bio-signal sensors, calculates a synchro rate of a plurality of bio-signal changes using a pulse analysis application, exposes an operation result as an event, and transmits the event as a short- A biometric information confirmation terminal; And
And an event processor for processing an event signal transmitted from the biometric information verification terminal to generate an event corresponding to a synchronization rate of a pulse change,
Wherein the biometric information verification terminal comprises: a control unit for controlling analysis of a plurality of received biometric information and controlling an occurrence of an event according to an analysis result; an application execution unit for executing a pulse analysis application in cooperation with the control unit; And a bio-signal analyzing unit for analyzing the bio-signal using a pulse analysis application executed in the unit for calculating the synchronization rate of the change of the first pulse signal and the second pulse signal,
The bio-signal analyzing unit converts the first and second pulse signals into a specific bar graph using the pulse analysis program included in the pulse analysis application, superimposes the converted bar graphs, And the pulse rate is calculated to analyze the living body signal. The system according to claim 7, wherein the biometric information verification terminal includes a display unit for visually displaying the received biometric signal.
The biometric information verification terminal of claim 7, wherein the biometric information verification terminal comprises: an event generation unit for generating an event corresponding to a synchronization rate of a pulse change analyzed by the bio-signal analysis unit under the control of the control unit; Further comprising an event information transmission unit for transmitting event information corresponding to a synchronization rate of a pulse change analyzed by the bio-signal analysis unit under the control of the control unit.
The method of claim 7, wherein the event processor includes an event processor for expressing a sync rate of a pulse change corresponding to the received event information,
Wherein the event processing unit expresses an event by combining the pulse change sync rate with the number of the lamps, or expresses the pulse change sync rate by the color density change.
[Claim 10] The system of claim 10, wherein the event processing unit processes the event by emitting a perfume corresponding to a pulse rate change syncrate.

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